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| datasheet 9dbu0531 march 9, 2017 1 ?2017 integrated device technology, inc. 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 description the 9dbu0531 is a member of idt's 1.5v ultra-low-power (ulp) pcie family. the device has 5 output enables for clock management, and 3 selectable smbus addresses. recommended application 1.5v pcie gen1-2-3 fanout buffer (fob) output features ? 5 1?167mhz low-power (lp) hcsl dif pairs key specifications ? dif additive cycle-to-cycle jitter < 5ps ? dif output-to-output skew < 60ps ? dif additive phase jitter is < 300fs rms for pcie gen3 ? dif additive phase jitter < 350fs rms for sgmii features/benefits ? lp-hcsl outputs; save 10 resistors compared to standard hcsl outputs ? 35mw typical power consumpt ion; eliminates thermal concerns ? spread spectrum (ss) comp atible; allows ss for emi reduction ? oe# pins for each output; support dif power management ? hcsl-compatible differential input; can be driven by common clock sources ? spread spectrum tolerant; allows reduction of emi ? smbus-selectable features; opt imize signal integrity to application ? slew rate for each output ? differential output amplitude ? device contains default confi guration; smbus interface not required for device operation ? 3.3v tolerant smbus interface works with legacy controllers ? 3 selectable smbus addresses; multiple devices can easily share an smbus segment ? 5 5 mm 32-vfqfpn; minimal board space block diagram , control logic ^ckpwrgd_pd# sdata_3.3 voe(4:0)# sclk_3.3 vsadr clk_in 5 dif4 dif3 dif2 dif1 dif0 clk_in#
5-output 1.5v pcie gen1-2-3 fanout buffer 2 march 9, 2017 9dbu0531 datasheet pin configuration smbus address selection table power management table power connections ^sadr_tri ^ckpwrgd_pd# gnd voe3# dif3# dif3 gnd vddo1.5 32 31 30 29 28 27 26 25 voe4# 1 24 voe2# dif4 2 23 dif2# dif4# 3 22 dif2 vddr1.5 4 21 vddo1.5 clk_in 5 20 gnd clk_in# 6 19 dif1# gndr 7 18 dif1 gnddig 817voe1# 9 10111213141516 vdddig1.5 sclk_3.3 sdata_3.3 voe0# dif0 dif0# gnd vddo1.5 32-pin vfqfpn, 5x5 mm, 0.5mm pitch v prefix indicates internal 120kohm pull down resistor 9dbu0531 epad is gnd ^ prefix indicates internal 120kohm pull up resistor ^v prefix indicates internal 120kohm pull up and pull down resistor ( biased to vdd/2 ) sadr address 0 1101011 m 1101100 1 1101101 x state of sadr on first application of ckpwrgd_pd# + read/write bit x x true o/p comp. o/p 0xxxlowlow 1 running 0 x low low 1 running 1 0 running running 1 running 1 1 low low clk_in oex# pin difx ckpwrgd_pd# smbus oex bit vdd gnd 47 98 16, 21, 25 15,20,26,30 note: epad on this device is not electrically connected to the die. it should be connected to ground for best thermal performance. dif outputs input receiver analo g digital power description pin number march 9, 2017 3 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet pin descriptions pin# pin name type pin description 1voe4# in active low input for enabling output 4. this pin has an internal 120kohm pull-down. 1 = disable outputs, 0 = enable outputs. 2 dif4 out differential true clock output. 3 dif4# out differential complementary clock output. 4 vddr1.5 pwr 1.5v power for differential input clock (receiver). this vdd should be treated as an analog power rail and filtered appropriately. 5 clk_in in true input for differential reference clock. 6 clk_in# in complementary input for differential reference clock. 7 gndr gnd analog ground pin for the differential input (receiver) 8 gnddig gnd ground pin for digital circuitry. 9 vdddig1.5 pwr 1.5v digital power (dirty power) 10 sclk_3.3 in clock pin of smbus circuitry, 3.3v tolerant. 11 sdata_3.3 i/o data pin for smbus circuitry, 3.3v tolerant. 12 voe0# in active low input for enabling output 0. this pin has an internal 120kohm pull-down. 1 = disable outputs, 0 = enable outputs. 13 dif0 out differential true clock output. 14 dif0# out differential complementary clock output. 15 gnd gnd ground pin. 16 vddo1.5 pwr power supply for outputs, nominally 1.5v. 17 voe1# in active low input for enabling output 1. this pin has an internal 120kohm pull-down. 1 = disable outputs, 0 = enable outputs. 18 dif1 out differential true clock output. 19 dif1# out differential complementary clock output. 20 gnd gnd ground pin. 21 vddo1.5 pwr power supply for outputs, nominally 1.5v. 22 dif2 out differential true clock output. 23 dif2# out differential complementary clock output. 24 voe2# in active low input for enabling output 2. this pin has an internal 120kohm pull-down. 1 = disable outputs, 0 = enable outputs. 25 vddo1.5 pwr power supply for outputs, nominally 1.5v. 26 gnd gnd ground pin. 27 dif3 out differential true clock output. 28 dif3# out differential complementary clock output. 29 voe3# in active low input for enabling output 3. this pin has an internal 120kohm pull-down. 1 = disable outputs, 0 = enable outputs. 30 gnd gnd ground pin. 31 ^ckpwrgd_pd# in input notifies device to sample latched inputs and start up on first high assertion. low enters power down mode, subsequent high assertions exit power down mode. this pin has internal 120kohm pull-up resistor. 32 ^sadr_tri latched in tri-level latch to select smbus address. it has an internal 120kohm pull up resistor. see smbus address selection table. 33 epad gnd connect epad to ground. 5-output 1.5v pcie gen1-2-3 fanout buffer 4 march 9, 2017 9dbu0531 datasheet test loads driving lvds rs rs low-power differential output test load 2pf 2pf 5 inches zo=100ohm note: the device can drive transmission line lengths greater than those allowed by the pcie sig alternate differential output terminations rs zo units 33 100 27 85 ohms rs device rs l4 driving lvds cc cc r7a r7b r8a r8b lvds clock input 3.3v driving lvds inputs receiver has termination receiver does not have termination r7a, r7b 10k ohm 140 ohm r8a, r8b 5.6k ohm 75 ohm cc 0.1f 0.1f vcm 1.2 volts 1.2 volts component value march 9, 2017 5 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet absolute maximum ratings stresses above the ratings lis ted below can cause permanent damage to the 9dbu0531. these rating s, which are standard values for idt commercially rated parts, are stress ratings on ly. functional operation of the device at these or any other conditions above those indicated in the operational sections of th e specifications is not implied. exposure to absolute maximum rating conditions for extended periods ca n affect product reliability. electrical parameters are guaranteed only over the recommended operating temperature range. electrical characteristi cs?clock input parameters parameter symbol conditions min typ max units notes supply voltage vddx applies to all vdd pins -0.5 2 v 1,2 input voltage v in -0.5 v dd +0.5 v 1, input high voltage, smbus v ihsmb smbus clock and data pins 3.3 v 1 storage temperature ts -65 150 c 1 junction temperature tj 125 c 1 input esd protection esd prot human body model 2000 v 1 1 guaranteed by design and characterization, not 100% tested in production. 2 operation under these conditions is neither implied nor guaranteed. 3 not to exceed 2.0v. ta = t amb , supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max units notes input common mode voltage - dif_in v com common mode input voltage 200 725 mv 1 input swing - dif_in v swing differential value 300 1450 mv 1 input slew rate - dif_in dv/dt measured differentially 0.4 8 v/ns 1,2 input leakage current i in v in = v dd , v in = gnd -5 5 a input duty cycle d tin measurement from differential waveform 45 50 55 % 1 input jitter - cycle to cycle j di fi n differential measurement 0 150 ps 1 1 guaranteed by design and characterization, not 100% tested in production. 2 slew rate measured through +/-75mv window centered around differential zero. 5-output 1.5v pcie gen1-2-3 fanout buffer 6 march 9, 2017 9dbu0531 datasheet electrical characteristics?input/supply /common parameters?normal operating conditions ta = t amb ; supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max units notes supply voltage vddx supply voltage for core and analog 1.425 1.5 1.575 v commercial range 0 25 70 c 1 industrial range -40 25 85 c 1 input high voltage v ih single-ended inputs, except smbus 0.75 v dd v dd + 0.3 v input mid voltage v im single-ended tri-level inputs ('_tri' suffix) 0.4 v dd 0.6 v dd v input low voltage v il single-ended inputs, except smbus -0.3 0.25 v dd v i in single-ended inputs, v in = gnd, v in = vdd -5 5 a i inp single-ended inputs v in = 0 v; inputs with internal pull-up resistors v in = vdd; inputs with internal pull-down resistors -200 200 a input frequency f in 1 167 mhz 2 pin inductance l p in 7nh1 c in logic inputs, except dif_in 1.5 5 pf 1 c i ndi f_i n dif_in differential clock inputs 1.5 2.7 pf 1,5 c ou t output pin capacitance 6 pf 1 clk stabilization t stab from v dd power-up and after input clock stabilization or de-assertion of pd# to 1st clock 1ms1,2 input ss modulation frequency pcie f modi npci e allowable frequency for pcie applications (triangular modulation) 30 33 khz input ss modulation frequency non-pcie f modi n allowable frequency for non-pcie applications (triangular modulation) 066khz oe# latency t latoe# dif start after oe# assertion dif stop after oe# deassertion 1 3 clocks 1,3 tdrive_pd# t drvpd dif output enable after pd# de-assertion 300 s 1,3 tfall t f fall time of single-ended control inputs 5 ns 2 trise t r rise time of single-ended control inputs 5 ns 2 smbus input low voltage v ilsmb 0.6 v smbus input high voltage v ihsmb v ddsmb = 3.3v, see note 4 for v ddsmb < 3.3v 2.1 3.3 v 4 smbus output low voltage v olsmb at i pullup 0.4 v smbus sink current i pullup at v ol 4ma nominal bus voltage v ddsmb bus voltage 1.425 3.6 v sclk/sdata rise time t rsmb (max vil - 0.15v) to (min vih + 0.15v) 1000 ns 1 sclk/sdata fall time t fsmb (min vih + 0.15v) to (max vil - 0.15v) 300 ns 1 smbus operating frequency f maxsmb maximum smbus operating frequency 400 khz 6 1 guaranteed by design and characterization, not 100% tested in production. 2 control input must be monotonic from 20% to 80% of input swing. 3 time from deassertion until outputs are > 200 mv. 4 for v ddsmb < 3.3v, v ihsmb > = 0.8xv ddsmb. 5 dif_in input. 6 the differential input clock must be running for the smbus to be active. ambient operating temperature input current capacitance t amb march 9, 2017 7 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet electrical characteristics? dif low-power hcsl outputs electrical characteristi cs?current consumption ta = t amb ; supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max units notes dv/dt scope averaging on, fast setting 1.4 2.3 3.5 v/ns 1,2,3 dv/dt scope averaging on, slow setting 0.9 1.5 2.5 v/ns 1,2,3 slew rate matching dv/dt slew rate matching, scope averaging on 9.3 20 % 1,2,4 voltage high v hi gh 630 750 850 7 voltage low v low -150 26 150 7 max voltage vmax 763 1150 7 min voltage vmin -300 22 7 vswing vswing scope averaging off 300 1448 mv 1,2 crossing voltage (abs) vcross_abs scope averaging off 250 390 550 mv 1,5 crossing voltage (var) -vcross scope averaging off 11 140 mv 1,6 2 measured from differential waveform mv 7 at default smbus settings. 1 guaranteed by design and characterization, not 100% tested in production. 3 slew rate is measured through the vswing voltage range centered around differential 0v. this results in a +/-150mv window arou nd differential 0v. 4 matching applies to rising edge rate for clock and falling edge rate for clock#. it is measured using a +/-75mv window centered on the average cross point where clock rising meets clock# falling. the median cross point is used to calculate the voltage thresh olds the oscilloscope is to use for the edge rate calculations. 5 vcross is defined as voltage where clock = clock# measured on a component test board and only applies to the differential risi ng edge (i.e. clock rising and clock# falling). 6 the total variation of all vcross measurements in any particular system. note that this is a subset of vcross_min/max (vcross absolute) allowed. the intent is to limit vcross induced modulation by setting -vcross to be smaller than vcross absolute. slew rate statistical measurement on single-ended signal using oscilloscope math function. (scope averaging on) mv measurement on single ended signal using absolute value. (scope averaging off) ta = t amb ; supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max units notes i ddr vddr at 100mhz 1.84 3 ma i dddi g vddig, all outputs at 100mhz 0.09 0.5 ma i ddao vddo1.5+vddo, all outputs at 100mhz 21 25 ma i ddrpd vddr, ckpwrgd_pd# = 0 0.001 0.3 ma 2 i dddi gpd vdddig, ckpwrgd_pd# = 0 0.1 0.2 ma 2 i ddaopd vddo1.5+vddo, ckpwrgd_pd# = 0 0.4 1 ma 2 1 guaranteed by design and characterization, not 100% tested in production. 2 input clock stopped. operating supply current powerdown current 5-output 1.5v pcie gen1-2-3 fanout buffer 8 march 9, 2017 9dbu0531 datasheet electrical characteristics?ou tput duty cycle, jitter, sk ew and pll characteristics electrical characteristics? phase jitter parameters ta = t amb ; supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max units notes duty cycle distortion t dcd measured differentially, at 100mhz -1 -0.2 0.5 % 1,3 skew, input to output t p dbyp v t = 50% 2400 2862 3700 ps 1 skew, output to output t sk3 v t = 50% 30 60 ps 1,4 jitter, cycle to cycle t jcyc-cyc additive jitter 0.1 5 ps 1,2 1 guaranteed by design and characterization, not 100% tested in production. 2 measured from differential waveform. 3 duty cycle distortion is the difference in duty cycle betw een the output and the input clock. 4 all outputs at default slew rate. ta = t amb ; supply voltages per normal operation conditions; see test loads for loading conditions parameter symbol conditions min typ max industry limit units notes t jp hpcieg1 pcie gen 1 0.1 5 n/a ps (p-p) 1,2,3,5 pcie gen 2 lo band 10khz < f < 1.5mhz 0.1 0.4 n/a ps (rms) 1,2,3,4, 5 pcie gen 2 high band 1.5mhz < f < nyquist (50mhz) 0.1 0.7 n/a ps (rms) 1,2,3,4 t jphpcieg3 pcie gen 3 (2-4mhz or 2-5mhz, cdr = 10mhz) 0.1 0.3 n/a ps (rms) 1,2,3,4 t jphsgmiim0 125mhz, 1.5mhz to 10mhz, -20db/decade rollover < 1.5mhz, -40db/decade rolloff > 10mhz 200 250 n/a fs (rms) 1,6 t jphsgmiim1 125mhz, 12khz to 20mhz, -20db/decade rollover < 1.5mhz, -40db/decade rolloff > 10mhz 313 350 n/a fs (rms) 1,6 1 guaranteed by design and characterization, not 100% tested in production. 4 for rms figures, additive jitter is calculated by solving the following equation: additive jitter = sqrt[(total jitter)^2 - (i nput jitter)^2]. 5 driven by 9fgv0831 or equivalent. 6 rohde & schwarz sma100. 2 see http://www.pcisig.com for complete specs. 3 sample size of at least 100k cycles. this figure extrapolates to 108ps pk-pk @ 1m cycles for a ber of 1-12. additive phase jitter t jphpcieg2 march 9, 2017 9 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet additive phase jitter plo t: 125m (12khz to 20mhz) rms additive jitter: 313fs 5-output 1.5v pcie gen1-2-3 fanout buffer 10 march 9, 2017 9dbu0531 datasheet general smbus serial interface information how to write ? controller (host) sends a start bit ? controller (host) sends the write address ? idt clock will acknowledge ? controller (host) sends the beginning byte location = n ? idt clock will acknowledge ? controller (host) sends the byte count = x ? idt clock will acknowledge ? controller (host) starts sending byte n through byte n+x-1 ? idt clock will acknowledg e each byte one at a time ? controller (host) sends a stop bit note: smbus address is latched on sadr pin. how to read ? controller (host) will send a start bit ? controller (host) sends the write address ? idt clock will acknowledge ? controller (host) sends the beginning byte location = n ? idt clock will acknowledge ? controller (host) will send a separate start bit ? controller (host) sends the read address ? idt clock will acknowledge ? idt clock will send the data byte count = x ? idt clock sends byte n+x-1 ? idt clock sends byte 0 through byte x (if x (h) was written to byte 8) ? controller (host) will need to acknowledge each byte ? controller (host) will send a not acknowledge bit ? controller (host) will send a stop bit index block write operation controller (host) idt (slave/receiver) tstart bit slave address wr write ack beginning byte = n ack data byte count = x ack beginning byte n x byte ack o o o o o o byte n + x - 1 ack pstop bit index block read operation controller (host) idt (slave/receiver) tstart bit slave address wr write ack beginning byte = n ack rt repeat start slave address rd read ack data byte count=x ack x byte beginning byte n ack o o o o o o byte n + x - 1 n not acknowledge pstop bit march 9, 2017 11 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet smbus table: output enable register 1 byte 0 name control function type 0 1 default bit 7 1 bit 6 dif oe3 output enable rw low/low enabled 1 bit 5 dif oe2 output enable rw low/low enabled 1 bit 4 1 bit 3 dif oe1 output enable rw low/low enabled 1 bit 2 1 bit 1 dif oe0 output enable rw low/low enabled 1 bit 0 1 1. a low on these bits will override the oe# pin and force the differential output low/low smbus table: pll operating mode and output amplitude control register byte 1 name control function type 0 1 default bit 7 0 bit 6 1 bit 5 dif oe4 output enable rw low/low enabled 1 bit 4 0 bit 3 1 bit 2 1 bit 1 amplitude 1 rw 00 = 0.55v 01= 0.65v 1 bit 0 amplitude 0 rw 10 = 0.7v 11 = 0.8v 0 1. a low on the dif oe bit will override the oe# pin and force the differential output low/low smbus table: dif slew rate control register byte 2 name control function type 0 1 default bit 7 1 bit 6 slewratesel dif3 slew rate selection rw slow setting fast setting 1 bit 5 slewratesel dif2 slew rate selection rw slow setting fast setting 1 bit 4 1 bit 3 slewratesel dif1 slew rate selection rw slow setting fast setting 1 bit 2 1 bit 1 slewratesel dif0 slew rate selection rw slow setting fast setting 1 bit 0 1 note: see "dif 0.7v low-power hcsl outputs" table for slew rates. smbus table: dif slew rate control register byte 3 name control function type 0 1 default bit 7 1 bit 6 1 bit 5 0 bit 4 0 bit 3 0 bit 2 1 bit 1 1 bit 0 slewratesel dif4 adjust slew rate of dif4 rw slow setting fast setting 1 note: see "dif 0.7v low-power hcsl outputs" table for slew rates. byte 4 is reserved and reads back 'hff controls output amplitude reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved reserved 5-output 1.5v pcie gen1-2-3 fanout buffer 12 march 9, 2017 9dbu0531 datasheet smbus table: revision and vendor id register byte 5 name control function type 0 1 default bit 7 rid3 r 0 bit 6 rid2 r 0 bit 5 rid1 r 0 bit 4 rid0 r 0 bit 3 vid3 r 0 bit 2 vid2 r 0 bit 1 vid1 r 0 bit 0 vid0 r 1 smbus table: device type/device id byte 6 name control function type 0 1 default bit 7 device type1 r 1 bit 6 device type0 r 1 bit 5 device id5 r 0 bit 4 device id4 r 0 bit 3 device id3 r 0 bit 2 device id2 r 1 bit 1 device id1 r 0 bit 0 device id0 r 1 smbus table: byte count register byte 7 name control function type 0 1 default bit 7 0 bit 6 0 bit 5 0 bit 4 bc4 rw 0 bit 3 bc3 rw 1 bit 2 bc2 rw 0 bit 1 bc1 rw 0 bit 0 bc0 rw 0 000101 binary or 05 hex reserved vendor id device id reserved a rev = 0000 00 = fgx, 01 = dbx, 10 = dmx, 11= dbx w/opll revision id 0001 = idt/ics device type byte count programming writing to this register will configure how many bytes will be read back, default is = 8 bytes. reserved march 9, 2017 13 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet marking diagrams notes: 1. ?lot? is the lot sequence number. 2. ?coo? denotes country of origin. 3. yyww is the last two digits of the year and week that the part was assembled. 4. line 2: truncated part number 5. ?l? denotes rohs compliant package. 6. ?i? denotes industrial temperature range device. thermal characteristics ics bu0531al yyww coo lot ics bu531ail yyww coo lot parameter symbol conditions pkg typ value units notes jc junction to case 42 c/w 1 c/w 1 c/w 1 c/w 1 c/w 1 ja5 junction to air, 5 m/s air flow 27 c/w 1 1 epad soldered to board nlg32 thermal resistance 5-output 1.5v pcie gen1-2-3 fanout buffer 14 march 9, 2017 9dbu0531 datasheet package outline and dimensions (nlg32) www.idt.com d it march 9, 2017 15 5-output 1.5v pcie gen1-2-3 fanout buffer 9dbu0531 datasheet package outline and dimensions (nlg32), cont. www.idt.com d it 5-output 1.5v pcie gen1-2-3 fanout buffer 16 march 9, 2017 9dbu0531 datasheet ordering information ?lf? suffix to the part number are the pb-free configuration and are rohs compliant. ?a? is the device revision designator (wil l not correlate with the datasheet revision). revision history part / order number shipping packaging package temperature 9dbu0531aklf trays 32-pin vfqfpn 0 to +70 c 9dbu0531aklft tape and reel 32-pin vfqfpn 0 to +70 c 9DBU0531AKILF trays 32-pin vfqfpn -40 to +85 c 9DBU0531AKILFt tape and reel 32-pin vfqfpn -40 to +85 c rev. initiator issue date description page # a rdw 7/15/2014 1. final electrical table update, move to ds to release various b rdw 7/24/2014 1. removed vddio reference in the electrical characteristics - input/supply/common parameters and absolute maximum ratings tables. this power rail does not exist on this device. the pinout and the pin descriptions are correct. 6 c rdw 9/19/2014 updated smbus input high/low parameters conditions, max values, and footnotes. 6 d rdw 4/22/2014 1. updated key specifications to be consistent across the family. 2. updated pin out and pin descriptions to show epad on package connected to ground. 3. updated clock input parameters table to be consistent with pcie vswing parameter. 4. add note about epad to power connections table. 1-3,5 e rdw 2/13/2017 1. updated pins 21 and 20 from vdda1.5/gnda to vddo1.5/gnd to clearly indicate that this part has no pll. 2, 3 f rdw 3/9/2017 1. removed "bypass mode" reference in "output duty cycle ..." and "phase jitter parameters" tables; update note 3 under output duty cycle table. 2. corrected spelling errors/typos. 3. change vdda to vddo1.5 in current consumption table. 4. update additive phase jitter conditions for pcie gen3. 7, 8 disclaimer integrated device technology, in c. (idt) and its affiliated companies (herei n referred to as ?idt?) reserve the righ t to modify the products and/or specificat ions described herein at any time, without notice, at idt?s sole discretion. perfor mance specifications and operating parameters of the described products are determined in an independent state and are not guaranteed to perform the same way when installed in customer products. the information contained herein is prov ided without representation or wa rranty of any kind, whether expr ess or implied, including, but not limited to, the suitab ility of idt's products for any particular purpose, an implied warranty of merchantability, or non-infri ngement of the intellectual property rights of others. this document is presented only as a guide and does not convey any license under intel- lectual property rights of idt or any third parties. idt's products are not intended for use in applications involving extreme environmental conditions or in life support systems o r similar devices where the failure or malfunction of an idt product can be reasonably expected to significantly affect the health or safety of users. anyone using an idt product in such a manner does so at their o wn risk, absent an express, written agreement by idt. integrated device technology, idt and the idt logo are trademarks or registered trademarks of idt and its subsidiaries in the u nited states and other countries. other trademarks used herein are the property of idt or their respective third party owners. for datashee t type definitions and a glossary of common terms, visit www.idt.com/go/glossary . integrated device technology , inc.. all rights reserved. corporate headquarters 6024 silver creek valley road san jose, ca 95138 usa www.idt.com sales 1-800-345-7015 or 408-284-8200 fax: 408-284-2775 www.idt.com/go/sales tech support www.idt.com/go/support 9dbu0531 march 9, 2017 17 ?2017 integrated device technology, inc. |
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